Anchored polysiloxane-modified polyurethane coatings and uses thereof

ABSTRACT

A polymeric material, prepared by reacting a mixture comprising a polyorganosiloxane having one or more isocyanate-reactive functional groups, polyisocyanate, and polyol, is provided. The isocyanate-reactive functional groups, typically one or two, are attached to only a single end of the polyorganosiloxane chains. The polymeric material may be used to form coatings on a substrate and to inhibit fouling on surfaces exposed to aqueous conditions.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority to and the benefit of U.S. Provisional Application Ser. No. 60/934,093, entitled Anchored Polysiloxane-Modified Polyurethane Coatings and Uses Thereof, filed Jun. 11, 2007, and U.S. Provisional Application Ser. No. 60/997,156, entitled Anchored Polysiloxane-Modified Polyurethane Coatings and Uses Thereof, filed Oct. 1, 2007, the specification, drawings, claims and abstract of which are incorporated herein by reference in their entirety.

GOVERNMENT RIGHTS STATEMENT

The U.S. Government has a paid-up license in this invention and the right in limited circumstances to require the patent owner to license others on terms as provided for by Grant No. N00014-06-1-0952 awarded by the Department of Defense, Office of Naval Research.

BACKGROUND

Fouling of ship hulls by marine organisms has plagued shipping activities for millennia. Fouling presents a significant drag penalty, reducing the efficiency of propulsion and resulting in the expenditure of excess fuel to overcome the drag in order to meet target cruising speed. Fouling also results in the transport of organisms from foreign ecosystems and can result in the introduction of invasive species. Thus, from both an operational and ecological point of view, methods to reduce or eliminate fouling are necessary. Biological fouling of marine organisms on ships has serious consequences for ship performance and mission capability. Fouling results in a rougher surface and an increase in the overall drag of the ship. These may result in substantial increases in fuel consumption and overall voyage cost.

Fouling release (“FR”) coatings appear to be a leading non-toxic alternative to biocide containing coatings. These are coating systems that do not necessarily prevent the settlement of marine organisms, but permit their easy removal with the application of shear to the surface of the coating. Ideally, the hydrodynamic shear on the hull as a ship reaches cruising velocity would be sufficient to remove fouling organisms. Coatings that are also easily cleaned using a water jet are, however, also desired. The most successful of such coatings to date are based on silicone elastomers. It has been shown that coatings with low modulus and low surface energy can often provide easy release of fouling organisms. Due to their low modulus, however, these coatings are very often easily damaged. In addition, such fouling release coatings may also suffer from poor adhesion, poor durability, and high cost.

SUMMARY

The present application is directed to a polymeric material which may be used to form fouling release coatings, e.g., for use in protecting boat hulls. The polymeric material may be prepared by reacting a mixture comprising: polyisocyanate; polyol; and polysiloxane having functional groups capable of reacting with the polyisocyanate. The polysiloxane component may have one or more functional groups capable of reacting with the polyisocyanate, where the isocyanate-reactive functional groups are attached to only a single end of the polyorganosiloxane chain(s). For example, the polysiloxane component may be an amino functional polyorganosiloxane, having one or more amino groups attached to a single end of the polyorganosiloxane chain.

The polymeric material may be used to form coatings which may have an initial water contact angle of at least about 90°. In some embodiments, the polymeric material may commonly have an initial water contact angle of at least about 100°, suitably may have an initial water contact angle of at least about 105°, and desirably may have an initial water contact angle of at least about 110°. In some embodiments, the water contact angle may change by no more than about 20° after immersion of the coating in deinonized water for 30 days. In some embodiments, the water contact angle may suitably change by no more than about 10°, and desirably the water contact angle may change by no more than about 5° after immersion of the coating in deinonized water for 30 days. In some embodiments, the polymeric material may be used to form a coating on a substrate which desirably has an initial pseudobarnacle pull off adhesion release force of no more than about 80N.

The polysiloxane components employed to form the present polymeric materials typically include polyorganosiloxane chain(s) which have a number average molecular weight of at least about 500. In some embodiments, the polyorganosiloxane may commonly have a number average molecular weight of at least about 1,000. In some embodiments, the polyorganosiloxane may desirably have a number average molecular weight of at least about 10,000.

In some embodiments, suitable polymeric materials may include those prepared by reacting a mixture comprising: an amino functional polyorganosiloxane (e.g., having a number average molecular weight of about 1,000 to 5,000); polyisocyanate; and polyol, such as a polycaprolactone polyol and/or a hydroxy-functional poly(meth)acrylate. In some embodiments, suitable polymeric materials may include those prepared by reacting a mixture comprising: an amino functional polyorganosiloxane (e.g., having a number average molecular weight of about 5,000 to 15,000); polyisocyanate; and polyol, such as a polycaprolactone polyol and/or a hydroxy-functional poly(meth)acrylate.

In one embodiment of the present application, crosslinked poly(dimethylsiloxane)-modified polyurethane coatings are described. Such coating can be formed from a mixture comprising the following components:

-   -   1. An organofunctional polysiloxane, such as         poly(dimethylsiloxane) (“PDMS”), where the polysiloxane has one         or more amino groups attached, typically via a linkage group, to         a single end of the polymer chain;     -   2. an organic polyol, which can include a polyester, polyether,         and/or acrylic polyol;     -   3. a polyisocyanate;     -   4. a catalyst to effect cure;     -   5. an optional pot-life extender; and     -   6. typically, one or more organic solvents.

In another embodiment of the present application, crosslinked polyorganosiloxane-modified polyurethane coatings may be formed from a mixture comprising: polyisocyanate; polyol; and polyorganosiloxane. The polyorganosiloxane may have one or more hydroxyalkyl carbamate groups attached, typically via a linkage group, to only a single end of the polymer chain. In certain embodiment, the polyorganosiloxane may include hydroxyl alkyl carbamate groups which include two or more hydroxy groups.

In other embodiments, crosslinked polyorganosiloxane-modified polyurethane coatings can be formed from a mixture comprising: polyisocyanate; polyol; and “star” polyorganosiloxane. For example, the “star” polyorganosiloxane may be prepared by reaction of a silane-terminated PDMS with a multifunctional reagent to form a molecule including one or more isocyanate-reactive functional group attached (e.g., via a linking group) to two or more PDMS polymer chains. The linking group may be a branched chain alkylene group, may include a hydroxyalkyl carbamate group and/or may include alkylene ether linkages. In some embodiments, the multifunctional reagent may comprise pentaerythritol triallyl ether, pentaerythritol diallyl ether and/or trimethylolpropane diallyl ether. Other suitable multifunctional reagents include partial allyl ethers of sorbitol or other similar polyols, e.g., reagents such as sorbitol di-, tri- or tetraallyl ethers.

The formation of crosslinked polyurethane coatings is well known in the literature and crosslinked polyurethane coatings are commonly formed from a mixture which includes an organic polyol and a polyisocyanate. Catalyst, pot life extender and/or solvents may also be included in formulations used to produce the present polymeric materials and coatings.

The organic polyols employed to form the present polymeric materials can be any polyol typically used to form crosslinked coatings. These can include polyester polyols, polyether polyols, polycarbonate polyols and acrylic polyols. A mixture of polyols can also be used in formulating a polyurethane coating. Polyester polyols can include those made from the melt polycondensation of polyfunctional acids with polyfunctional alcohols or those made from the ring opening polymerization of cyclic monomers such as epsilon-caprolactone. Acrylic polyols are typically made from the free radical polymerization of a mixture of ethylenically unsaturated monomers. One of the monomers must bear a hydroxyl functional group. Hydroxy-functional monomers include hydroxyethyl acrylate, hydroxyethylmethacrylate, hydroxypropyl acrylate, and hydroxypropyl methacrylate.

In other embodiments, the present polymeric material may be prepared by reacting a mixture comprising: polyisocyanate; polyol; and a polysiloxane component having two or more polyorganosiloxane chains attached to a linker molecule, which has one or more functional groups capable of reacting with the polyisocyanate. For example, the polysiloxane component may have formula I:

where R′Si— is a terminal group; n is about 10 to 1,000; LINK is a linking group; X is —OH or —NH₂; and y is an integer from 1 to 4. Examples of suitable linking groups (“LINK”) include alkylene groups, which may have one or more oxygen, nitrogen or sulfur atoms substituted for a carbon atom of its backbone. Typically, the linking group has no more than about 10 atoms in its backbone. Suitable R′Si— terminal groups may be trialkylsilyl groups, such as R₃ Si— groups, e.g., Me₃Si—, or R¹R₂ Si— groups, e.g., BuMe₂Si—.

In other embodiments, the present polymeric material may be prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane having two or more functional groups capable of reacting with the polyisocyanate attached to only a single end of the polyorganosiloxane; and polyol. The polyorganosiloxane typically has (a) two or more amino groups or (b) two or more hydroxy groups attached to only a single end of the polyorganosiloxane.

Methods of inhibiting fouling on a surface exposed to aquatic conditions, such as a boat hull, comprising applying a fouling release coating composition to at least a portion of said surface hull are also provided. The application also describes surfaces designed to be exposed to aqueous conditions (e.g., salt water conditions, such as seawater or brackish water, or fresh water conditions, such as found with materials in contact with lake or stream water), which are protected with a coating including the polymeric materials described in the present application.

By synthesizing polysiloxane-modified (e.g., PDMS-modified) polyurethane coatings, it can be possible to generate coatings that have low surface energy surfaces, where the surfaces maintain low surface energy under water due to the crosslinking. The coatings may also be tough and have good adhesion to various substrates. The components can be mixed together and the applied to the substrate where the solvent evaporates and crosslinking takes place. Due to the low surface energy of the polysiloxane, this component may tend to preferentially rise to the surface of the coating. However, due to the isocyanate-reactive functional end group(s), e.g., amino-functional end group(s), the polysiloxane can react with isocyanate functional groups and become anchored to the polymer network.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts a cross section of an anchored polysiloxane coating formed using the present method, wherein the coating includes a mono-functional polysiloxane, such as a mono amino functional PDMS, anchored in a polyurethane matrix.

FIG. 2 depicts a cross section of an anchored polysiloxane coating as in FIG. 1, wherein the PDMS molecular weight is higher than the PDMS molecular weight in FIG. 1.

FIG. 3 depicts a siloxane-polyurethane coating made from monofunctional “star” PDMS.

FIG. 4 shows biofilm retention data for C. lytica bioassay, quantified by staining with crystal violet, extraction, and absorbance measurements.

FIG. 5 shows: Navicula attachment data for the experimental and reference coatings; the chloroform fluorescence measurement illustrates the relative number of organisms attached to the coating surface.

FIG. 6 shows N. incerta removal after 10 psi water jetting for 10 sec.

FIG. 7 shows Ulva sporeling attachment, as measured by the extraction of chlorophyll; each point is the mean of 6 replicates and the error bars show 95% confidence limits.

FIG. 8 shows water jet removal of Ulva sporelings after 7 days growth using an impact pressure of 67 kPa; each point is the mean of 6 replicates and the error bars show 95% confidence limits.

DETAILED DESCRIPTION

To provide coatings that exhibit fouling release behavior while also yielding improved durability, self-stratifying coatings that phase separate into a low surface energy, low modulus top layer, with a tougher lower layer can be designed. Self-stratifying coatings are coatings that are applied in a single step, but then spontaneously phase separate into two or more distinct layers upon application and film formation. Surface energy and viscosity are the main driving and/or controlling forces for self-stratification. A coating composed of polymeric material with poly(dialkylsiloxane) (e.g., poly(dimethylsiloxane); “PDMS”) and polyurethane subunits may meet these requirements. Since surface energy is a primary driving force, the PDMS component will form the top, low energy, rubbery layer. The polyurethane component can form a tough durable underlayer. An additional advantage of this system is that the isocyanate resins used to form the polyurethane may react with residual hydroxyl groups on an epoxy anticorrosion primer, providing good adhesion, thus eliminating the need for a tie layer between the corrosion coating and the fouling-release coating.

The preparation of siloxane-polyurethane coatings can be carried out using PDMS polymers that have organofunctional groups at one end of the polymer chain. One or more amino functional groups can be present at the chain end. In many reported siloxane-polyurethane coatings, both ends of the PDMS chain are tethered to the coating and can potentially restrict the mobility of the PDMS segments on the surface of the coating. Coatings that have a polysiloxane, such as PDMS, tethered at only one end, can result in a highly mobile surface and may permit easier release of fouling organisms as illustrated in FIGS. 1 and 2.

Monofunctional PDMS polymers can be synthesized through the anionic ring-opening polymerization of hexamethylcyclotrisiloxane (“D3”), a cyclic siloxane trimer, using an anionic initiator (see, e.g., Scheme 1). The PDMS chain can be terminated, e.g., using dimethyl chlorosilane, followed by hydrosilation to convert the chain end to the desired functional group.

The synthetic scheme for the synthesis of aminopropyl terminated PDMS is shown in Scheme 2. The molecular weight of the PDMS can be readily varied by changing the ratio of the D3 to the lithium trimethylsiloxanoate initiator. Polysiloxanes having molecular weights from 500 to 30,000 g/mol can be readily prepared using this type of method. The amount of PDMS incorporated into the siloxane-polyurethane coating system can be varied, e.g., from about 0.1 weight percent up to 30 weight percent. The amount of PDMS incorporated into the siloxane-polyurethane coating system can be varied from 0.1 weight percent up to 30 weight percent. Siloxane-polyurethane coating system incorporating about 0.5 to 10 wt. % PDMS are quite suitable for many coating applications.

Suitable anionic initiators can include lithium trimethylsiloxanoate, n-butyl lithium and the like.

An additional advantage of using the mono-terminated PDMS is that it can be pre-reacted with the isocyanate crosslinker without gelation to form an adduct. This adduct can then be mixed with the organic polyol just prior to application to a surface to form a coating.

Several aminopropyl monoterminated PDMS were synthesized having a range of molecular weights from 2,000 to 30,000 (theoretical). These aminopropyl monoterminated PDMS were incorporated into a siloxane-polyurethane coating formulation containing a polycaprolactone polyol (Tone 0305 from Dow Chemical), and a polyisocyanate based on isophorone diisocyanate (IDT70B from Rhodia). The catalyst used was dibutyl tin diacetate (“DBTDA”). Coatings were prepared using 5 and 10% of the mono-amino functional PDMS. Coatings were tested for pseudobarnacle adhesion and surface energy initially as-made and after immersion in deionized water for 30 days. A siloxane-polyurethane coating incorporating the mono-aminopropyl terminated PDMS had low surface energy and very low pseudobarnacle adhesion. The data are shown in Table 1 and 2, below.

TABLE 1 Pseudobarnacle adhesion of siloxane-polyurethane coatings. 10% PDMS 5% PDMS After After Before Water Water Before Water Water Theoretical Immersion Immersion Immersion Immersion MW (g/mol) (N) (N) (N) (N) 30,000 8.75 8.17 Not Prepared 5,000 8.20 — 9.60 — 2,000 8.71 8.49 8.60 8.53 5,000 8.76 8.46 8.81 8.53 3,000 8.66 — 8.70 —

TABLE 2 Contact angle and surface energy data for siloxane-polyurethane coatings. 10% PDMS 5% PDMS Before Water After Water Before Water After Water Immersion Immersion Immersion Immersion Surface Surface Surface Surface Theoretical Water M.I. Energy Water M.I. Energy Water M.I. Energy Water Energy MW (g/mol) CA CA (mN/m) CA CA (mN/m) CA CA (mN/m) CA M.I. CA (mN/m) 30,000  107.8 74.2 20.9 103.6 78.4 19.6 Not Prepared 5,000 106.5 73.3 21.5 — 107.0 73.7 21.2 — 2,000 104.1 71.0 22.9 107.1 78.3 19.0 106.0 70.5 22.9 98.2 76.3 21.7 5,000 107.4 72.6 21.8 100.8 76.5 20.9 106.7 71.3 22.5 98.9 75.0 22.0 3,000 105.7 69.0 23.7 — 101.8 69.8 23.8 —

Other unique modified polysiloxane structures can be prepared by reacting an aminopropyl mono-terminated PDMS with a cyclic carbonate such as ethylene carbonate, propylene carbonate, or glycerin carbonate (see Scheme 3). Reaction with ethylene carbonate or propylene carbonate results in a hydroxyl alkyl carbamate mono-terminated polysiloxane.

Reaction with glycerin carbonate results in a dihydroxy alkyl carbamate mono-terminated PDMS. This PDMS polymer has two reactive functional groups (the hydroxyls) at one end of the polymer chain. As above, use of this functionalized polysiloxane could result in a highly mobile surface, providing low surface energy and low adhesion of fouling organisms, however, it can be incorporated into a cross linked polymer network quite differently than the siloxane polymers having a single functional chain. Reaction with ethylene carbonate or propylene carbonate results in a hydroxyl alkyl carbamate mono-terminated PDMS.

Additional architectures of the PDMS polymer are also possible using the synthetic strategy shown in Scheme 2. For example, the silane terminated PDMS can be reacted with a multifunctional reagent such as pentaerythritol triallyl ether to yield a hydroxyl-functional PDMS “star”, as shown in Scheme 4. When incorporated into a polyurethane coating, this architecture has the potential to yield a highly mobile PDMS surface due to the branched structure of the PDMS. A model for the possible morphology of a siloxane-polyurethane coating made from this “star” PDMS is shown in FIG. 3.

A similar material can also be synthesized from trimethylolpropane diallyl ether and is illustrated in Scheme 5. This is a unique polymer in that it has a single isocyanate reactive functional group in the middle of a PDMS polymer.

To form the siloxane-polyurethane coatings from these polymers, the siloxane is typically combined with an additional organic polyol plus a polyisocyanate. Optionally, a catalyst may be present to accelerate the curing and solvents may also be used. In addition, a pot life extender may be used in the coating formulation.

The organic polyol may be a polyether polyol, such as poly(ethyleneglycol), poly(propylene glycol), poly(butylene glycol) or poly(tetramethylene oxide); a polycarbonate polyol, a polyester polyol, or an acrylic polyol. Examples of suitable polyester polyols are poly(caprolactone) polyols or poly(hexamethylene adipate) and the like.

Acrylic polyols may be synthesized from a mixture of at least one hydroxy functional monomer plus one or more non-functional monomers. Suitable hydroxy functional monomers are hydroxyethyl acrylate, hydroxyethyl methacrylate, hydroxypropyl acrylate, hydroxypropyl methacrylate and the like. Examples of non-functional monomers are styrene, methyl methacrylate, methyl acrylate, butyl methacrylate, butyl acrylate, lauryl methacrylate, lauryl acrylate, 2-ethylhexyl acrylate, 2-ethyl hexyl methacrylate and the like. The acrylic polyol is synthesized in solution using a thermally-activated free radical initiator. The polyol can be synthesized in either a batch, semi-batch or continuous process. Examples of free radical initiators are benzoyl peroxide, t-amyl peroxy-2-ethylhexanoate, t-butyl hydroperoxide, di-t-butyl peroxide, azobisisobutyronitrile, azobisisovaleronitrile, and the like.

Solvents for the acrylic polyol polymerization can be toluene, xylene, methylisobutyl ketone, etc. The polymerization is conducted at a temperature suitable to effect polymerization in a reasonable period of time and is dependent on the initiator used. Polymerization can be carried out in the range of 70° C. to 180° C.

The polyisocyanate used in the invention can be either aromatic or aliphatic, or cycloaliphatic. Polyisocyanates based on methylene diphenyl diisocyanate (“MDI”), hexamethylene diisocyanate, isophorone diisocyanate, and the like can be used.

Catalysts for the crosslinking can be either organometallic complexes or organic bases. Examples of organometallic compounds are dibutyl tin dilaurate, dibutyl tin diacetate, bismuth carboxylate, and compounds of zirconium and aluminum such as K-Kat 4205, K-Kat-5218, and K-Kat-XC-6212. Examples of organic base catalysts are sold under the DABCO trade name by Air Products. DABCO is 1,4-diazabicyclo[2.2.2]octane.

Solvents used in the formulation can be solvents typical of that used in coatings systems. These can include toluene, xylene, methyl ethyl ketone, methyl amyl ketone, methyl isobutyl ketone, butyl acetate, t-butyl acetate, ethyl ethoxy propioniate, isopropanol and the like.

Pot life extenders can include volatile compounds that inhibit the curing reaction such as 2-4-pentanedione.

Pigments can be included in the formulation if a coating having a particular color is desired.

The siloxane-polyurethane coatings may commonly have an initial water contact angle of at least about 90°, suitably of at least about 100°, more suitably of at least about 105°, and desirably of at least about 110°. The water contact angle may commonly change after immersion of the polymeric material in deinonized water for 30 days no more than about 20°, suitably no more than about 10°, and desirably no more than about 5°. The polymeric material may commonly have an initial pseudobarnacle pull off adhesion release force of no more than about 80N.

EXAMPLES

The following examples are presented to illustrate the compositions and methods described herein, and to assist one of ordinary skill in making and using the same. The examples are not intended in any way to otherwise limit the scope of the invention.

Example 1 Synthesis of Aminopropyl Terminated PDMS and Use in Coatings Synthesis of APT-PDMS-M

Synthesis of the monofunctional aminopropyl terminated oligomer (“APT-PDMS-M”) is carried out in two steps. In the first step, anionic polymerization is carried out to synthesize a silane-terminated macromer. Then, the macromer is functionalized through hydrosilation with protected allyl amine (see Scheme 2).

Macromer Synthesis

Hexamethylcyclotrisiloxane (“D3”) was dissolved in tetrahydrofuran (“THF”) at a concentration of 50 wt %. The solution was degassed by bubbling nitrogen (“N₂”) gas through it. Lithium trimethylsilanolate (“LTMS”) salt was added to the solution to initiate polymerization at room temperature. The amount of LTMS added was varied in molar ratios to D3 to achieve four molecular weights (1,000, 5,000, 10,000, and 15,000 g/mol). After 24 hours of reaction time, the living polymerization was terminated by the addition of diemthylchlorosilane (“CDMS”) at 2-5° C. The terminating agent, CDMS, was added in excess (100% molar) to ensure termination of all “living” polymer chain ends. Table 3 summarizes the amounts of D3 monomer solution, LTMS initiator, and CDMS terminating agent that were used for the polymerization and termination. The solutions were filtered to remove THF and a lithium chloride (“LiCl”) salt precipitate formed, causing the polymer to appear cloudy. The LiCl precipitate was removed by vacuum filtration to yield a clear, monohydride terminated poly(dimethyl siloxane) (“PDMS”) macromer (“HT-PDMS-M”). The synthetic procedure for the PDMS macromer synthesis is shown in Scheme 6.

TABLE 3 Amount of D3 and LTMS used to polymerize PDMS macromers of various molecular weights. Theoretical MW D3 LTMS CDMS (g/mol) D3 Soln* (g) Mass (g) mMoles Mass (g) mMoles Mass (g) mMoles 1,000 100.0 50.0 220 4.87 50.8 9.6 101.5 5,000 100.0 50.0 220 0.96 10.0 1.9 20.1 10,000 100.0 50.0 220 0.48 5.0 0.9 9.9 15,000 100.0 50.0 220 0.32 3.3 0.6 6.7 *50% wt solution in THF

Macromer Functionalization

A protected allylamine, N-Allyl-N,N-bis(trimethylsilyl)amine (“Allyl-HMDS”), was added to the HT-PDMS-M. Hydrosilylation was carried out at 60° C. in the presence of Karstedt catalyst (Platinum(0)-1,3-divinyl-1,1,3,3-tetramethyldisiloxane complex) of which 1 drop of solution in xylene had been added. Table 4 summarizes the reaction times and reagents used to carry out the hydrosilylation reactions. The products of the hydrosilylation reactions were called disilazane terminated PDMS macromers (“DT-PDMS-M”). The primary amine groups of the DT-PDMS-M were then deprotected by washing with methanol (30 mL) to yield aminopropyl terminated PDMS macromers (“APT-PDMS-M”). The synthetic procedure for functionalization of the PDMS macromers is shown in Scheme 7.

TABLE 4 Reaction times and reagent amounts used for hydrosilylation reactions Theoretical HT-PDMS- Allyl-HMDS Reaction time MW (g/mol) M (g) Mass (g) mMoles (hrs) 1,000 33.3 12.5 62.0 22 5,000 38.5 5.3 26.3 22 10,000 39.2 2.4 11.9 22 15,000 39.5 2.0 9.9 22

Characterization of PDMS Macromers

The HT-PDMS-M were characterized using gel permeation chromatography (“GPC”), to confirm the molecular weight of the macromers. The number average molecular weight (“MW”), weight average MW, and polydispersity index (“PDI”) obtained from GPC analysis, relative to polystyrene standards, are shown in Table 5.

TABLE 5 Molecular weight data for HT-PDMS-M. Theoretical Number Weight MW average average (g/mol) MW MW PDI 1,000 2,200 2,500 1.17 5,000 6,700 8,700 1.3 10,000 11,300 15,500 1.38 15,000 12,100 16,700 1.38

Coating Formulation

Polyurethane (“PU”)—PDMS coating formulations were prepared using the APT-PDMS-M, isophorone diisocyanate trimer (“IDT”, 70% in butyl acetate (“BA”), Tolonate IDT 70B), a polycaprolactone polyol (“PCL”, Tone polyol 0305), dibutyltin diacetate (“DBTDAc”) as a catalyst, 2,4-pentanedione (“PD”) as a pot-life extender and methyl amyl ketone (“MAK”) and ethyl 3-ethoxypropionate (“EEP”) as solvents. The APT-PDMS-Ms (30% in EEP), PCL polyol (90% in MAK) and DBTDAc (1% in MAK) were used as solutions for formulation purposes while Tolonate IDT 70B was used as supplied (70% in BA). The coatings were formulated with a 1.1:1 ratio of isocyanate to hydroxyl and amine equivalents. The coating formulations are outlined in Table 6 with reagent quantities for approximately 10 grams of total formulation. The coating formulations were prepared by first mixing the APT-PDMS-M solutions with IDT for 1 hour. The PD was added and the formulation was mixed. The addition of PCL polyol and DBTDAc solutions followed in that order. The compositions of the coating formulations are summarized in Table 7.

TABLE 6 PU-PDMS coating formulation recipes Theoretical 30% Tolonate 90% PCL 1% Coating MW PDMS PDMS in IDT polyol in DBTDAc ID (g/mol) EEP (g) 70B (g) MAK (g) in MAK 1 1,000 1.08 5.98 2.21 0.10 2 1,000 2.16 5.68 2.08 0.10 3 5,000 1.08 5.98 2.21 0.10 4 5,000 2.16 5.68 2.08 0.10 5 10,000 1.08 5.98 2.21 0.10 6 10,000 2.16 5.68 2.08 0.10 7 15,000 1.08 5.98 2.21 0.10 8 15,000 2.16 5.68 2.08 0.10 9 (PU) NA 0.00 6.29 2.33 0.10

TABLE 7 Coating formulation composition of PU-PDMS coatings used to prepare coatings for bioassay testing PD Theoretical (based MW Weight % of Solids DBTDAc Weight on Coating PDMS PCL Total (% total % of Solvent total ID (g/mol) PDMS IDT polyol Solids solids) BA EEP MAK formulation) 1 1,000 5% 64% 31% 69% 0.015% 63% 26% 11% 10% 2 1,000 10% 61% 29% 65% 0.015% 48% 43% 9% 10% 3 5,000 5% 64% 31% 69% 0.015% 63% 26% 11% 10% 4 5,000 10% 61% 29% 65% 0.015% 48% 43% 9% 10% 5 10,000 5% 64% 31% 69% 0.015% 63% 26% 11% 10% 6 10,000 10% 61% 29% 65% 0.015% 48% 43% 9% 10% 7 15,000 5% 64% 31% 69% 0.015% 63% 26% 11% 10% 8 15,000 10% 61% 29% 65% 0.015% 48% 43% 9% 10% 9 (PU) NA 0% 68% 32% 75% 0.015% 85% 0% 15% 10%

Coating Preparation

The coatings were prepared by drawdown (10 mil wet thickness) onto 4″×8″ aluminum Q-panels in an array format using an automated coating application instrument (Symyx). The coatings were also manually dispensed into 24-well microtiter plates with primed aluminum discs adhered at the base of each well using a repeat volume pipettor (250 μL per well). The coatings were cured at ambient conditions overnight and then oven cured at 80° C. for 45 minutes the following morning. Silicone controls coatings, DC 3140 and T2 Silastic, were prepared in the same way, but curing was performed at ambient conditions for 24 hours and the samples were not oven cured.

Pseudobarnacle Adhesion

Pseudobarnacle adhesion (“PB”) was performed on the coatings approximately 20 hours after initial attachment of the test studs. This test was performed before and after 21 days of water immersion. The results from this test are outlined in Table 8. The values reported are averages of three measurements, unless otherwise noted. Overall, the siloxane-polyurethane coatings showed very low PB adhesion, showing removal forces much lower than the polyurethane without siloxane and also lower than the silicone controls. The results for the siloxane-polyurethane coatings are also similar before and after water immersion, indicating that the coatings are stable under water.

TABLE 8 Pseudobarnacle adhesion results before and after water immersion. The values reported are the averages of three measurements, unless otherwise reported. Before Water After 21 d Water Immersion Immersion Avg Release Std Dev Release Std Dev Coating Force (N) (N) Force (N) (N) 1 14.1 9.41 8.4 0.55 2 8.7 0.07 8.7 0.20 3 8.6 0.03 8.5 0.03 4 9.4 1.56 8.5 0.10 5 8.2* 0.29 8.5 0.00 6 8.4 0.02 8.5 0.05 7 (PU control) 89.8 3.94 Not Tested NA DC 10.3 1.56 Not Tested NA DC 13.9 6.39 Not Tested NA T2 17.2 7.83 Not Tested NA T2 12.6* 5.48 Not Tested NA *Only 2 measurements were included (3^(rd) measurement was near 1N and determined as an outlier)

Contact Angle and Surface Energy

Contact angle (“CA”) measurements were performed on coatings on 4″×8″ aluminum panels using water and methylene iodide (“MeI”) before and after 21 days of water immersion. Table 9 summarizes the water and MeI contact angles, along with surface energy (“SE”) before and after water immersion. The reported values are the averages of three measurements. The data confirm that the coatings are stable when immersed in water and do not rearrange to yield a more hydrophilic surface due to the crosslinked nature of the films. Furthermore, the coatings exhibited low surface energy compared to the PU control, confirming the presence of PDMS at the surface of the coatings.

TABLE 9 Water contact angle measurements on experimental coatings. Before Water Immersion After Water Immersion Water MeI Water MeI Std Std Std Std CA Dev CA Dev SE CA Dev CA Dev SE Coating (°) (°) (°) (°) (mN/m) (°) (°) (°) (°) (mN/m) 1 102.2 1.6 62.8 2.1 27.4 90.6 0.9 68.3 1.2 27.3 2 105.3 0.5 69.7 2.3 23.4 92.1 0.2 64.4 1.1 28.5 3 106.5 0.9 68.0 1.4 24.2 93.6 1.0 68.8 1.2 26.1 4 105.0 1.1 69.8 1.3 23.4 105.7 0.6 72.7 2.1 21.9 5 106.1 0.7 67.7 5.3 24.5 106.5 0.4 72.6 1.3 21.8 6 105.8 1.2 71.7 0.9 22.4 105.4 1.6 71.9 2.5 22.3 7 106.9 0.9 69.9 1.6 23.2 106.9 1.2 72.9 0.4 21.6 8 106.4 0.3 72.0 1.7 22.1 105.4 0.5 70.3 0.3 23.1 9 (PU 88.3 0.6 47.3 1.9 37.6 73.1 1.0 63.4 1.7 36.9 control) DC 114.5 0.7 94.6 4.8 11.4 109.7 1.2 90.4 6.4 13.6 DC 112.8 0.5 88.0 6.8 11.3 107.6 2.7 83.9 10.5 16.5 T2 114.3 0.4 95.7 2.1 14.0 108.8 1.0 90.5 1.9 13.8 T2 110.8 4.0 94.6 1.8 12.0 104.0 3.8 87.0 1.6 16.0 C. lytica Biofilm Retention

The data from the C. lytica biofilm retention (performed on coatings deposited in 24-well plate) bioassay is shown in FIG. 4. The C. lytica was allowed to attach in from a 5% culture. A growth period of 24 hours was allowed, followed by rinsing in triplicate and staining with crystal violet (“CV’). Acetic acid was used to extract the CV stain and the absorbance of the extract solution was measured at 600 nm. Very low biofilm retention was observed for all of the experimental coatings, which exhibited lower retention than the silicone controls. In addition, leachate toxicity was not observed.

N. incerta Bioassay

The data from the Navicula incerta attachment bioassay is shown in FIG. 5, illustrating the amount of diatoms that initially attached to the coatings (performed on coatings deposited in 24-well plate). The N. incerta was allowed to attach to the coatings for 2 hours (0.03 OD culture), the chlorophyll was extracted with DMSO, and fluorescence was measured to determine the relative amounts of attached organisms. Coatings 2 and 6 showed very low attachment of N. incerta while coatings 5 and 8 showed reduced N. incerta attachment compared to the other experimental and reference coatings. Coatings 1, 3, 4, and 7 showed a similar level of attachment as the DC, T2, and PU control coatings. FIG. 6 shows data obtained when the attached N. incerta were removed by water jetting. The same attachment procedure was used as previously described; the samples were exposed to a 10 psi water jet, and the attachment was quantified in the manner described above. While low values of attachment are desired, a high level of removal of the organisms is desired, and was observed in some cases, as shown in FIG. 6. Coating 2 showed the highest level of N. incerta removal while coatings 1, 4, and 7 showed moderate removal and 3, 5, and 8 showed low removal and coating 6 showed no removal at all. While the identification of a trend is difficult in the case of this data, the coatings with higher molecular weight PDMS (10,000 g/mol and 15,000 g/mol) seemed to show reduced attachment and greater release compared to those prepared with lower molecular weight PDMS.

Barnacle Reattachment Bioassay

Barnacle reattachment was performed by allowing live barnacles to reattach to the surface of the coatings for a period of 14 days after removal from a silicone surface. Testing was performed on coatings applied to A1 panels. The barnacles were removed using a digital force gauge and their removal forces were recorded. Initially, the test was performed at 14 days of water immersion and very low barnacle reattachment forces were obtained (Table 10). However, when the procedure was repeated on coatings that had been subjected to water immersion for 49 days, higher removal forces were obtained. Although the reattachment forces were higher for the coatings subjected to the longer water immersion time, the coatings with higher molecular weight PDMS (10,000 g/mol and 15,000 g/mol) performed the best in both cases, with lower release forces than the other coatings, including the silicone controls.

TABLE 10 Barnacle reattachment data for experimental coating with 14 and 49 days of pre-leaching. 14 days of pre-leaching 49 days of pre-leaching Mean Mean Reattached Reattached Adhesion Std Dev Adhesion Std Dev Coating ID (Mpa) (Mpa) n (Mpa) (Mpa) n 1 0.16 0.09 9 0.56 0.20 5 2 0.18 0.11 9 0.53 0.16 7 3 0.09 0.06 9 0.55 0.07 6 4 0.03 0.04 7 0.42 0.12 8 5 0.02 0.01 6 0.27 0.10 9 6 0.03 0.01 7 0.15 0.05 8 7 0.02 0.01 7 0.20 0.08 8 8 0.02 0.01 6 0.10 0.04 7 9 (PU control) 0.24 0.13 9 0.48 0.03 5 DC 3140 0.19 0.11 8 0.31 0.11 7 T2 0.30 0.16 6 0.34 0.13 9 N. incerta Bioassay

A similar bioassay to the N. incerta assay described above was performed on the same coatings (on A1 panels), excluding the PU control (Coating 9), but with the addition of an Intersleek fouling-release control. However, attachment was allowed until a thick biofilm was observed, water jetting was performed to remove the biofilm and removal was estimated visually. The results from the water jet removal are outlined in Table 11. In general, the coatings prepared with the lower molecular weight PDMS (1,000 g/mol and 5,000 g/mol) showed greater diatom release than those prepared with the higher molecular weight PDMS macromers.

TABLE 11 Summary of diatom release at various water jet pressures % removal at impact pressure Coating 64 kPa 73 kPa 93 kPa 132 kPa IS 100 — — — DC 40 100 100 100 T2 20 100 100 100 1 100 100 100 100 2 100 100 100 100 3 70 90 50 70 4 90 70 75 60 5 5 5 95 95 6 5 0 50 50 7 35 70 95 100 8 40 50 100 100

Ulva Sporeling Bioassay

Fouling-release studies using Ulva sporelings were carried out. Ulva sporelings were allowed to adhere to the test coatings (deposited into 24-well plates) for seven days and the amount of attachment was measured by extracting the chlorophyll and measuring fluorescence. This data are shown in FIG. 7 as the mean of 6 replicates and error bars representing 95% confidence limits. The sporelings were removed by water jetting at 64 kPa and this data is shown in FIG. 8. Coatings 5, 6, 7, and 8 performed comparably to the T2 control (60-80% removal), which is typically performs well as a fouling-release coating in this bioassay. The other coatings also had better removal than the polyurethane without the siloxane.

Example 2 Synthesis of Branched PDMS and Use in Coatings Macromer Synthesis

Hexamethylcyclotrisiloxane (“D3”) was dissolved in tetrahydrofuran (“THF”) at a concentration of 50 wt %. The solution was degassed by bubbling nitrogen (“N₂”) gas through it. Lithium trimethylsilanolate (“LTMS”) salt solution (1.0M in CH₂Cl₂) was added to the solution to initiate polymerization at room temperature. The amounts of LTMS and D3 added were in the appropriate molar ratios to achieve a final molecular weight of 5,000 g/mol. After 24 hours of reaction time, the living polymerization was terminated by the addition of dimethylchlorosilane (“CDMS”) at 2-5° C. The terminating agent, CDMS, was added in excess to ensure termination of all “living” polymer chain ends. The amount of D3 monomer solution, LTMS initiator, and CDMS terminating agent that were used for the polymerization and termination are shown in Table 12. The solutions were rotary evaporated to remove THF and excess CDMS. A lithium chloride (“LiCl”) precipitate, caused the polymer to appear cloudy. The LiCl precipitate was removed by vacuum filtration to yield a clear, monohydride terminated poly(dimethyl siloxane) (“PDMS”) macromer (“HT-PDMS-M”).

TABLE 12 Amounts of D3, LTMS and CDMS used in polymerization and termination of 5000 g/mol PDMS macromer. LTMS soln 1.0M Theoretical D3 (CH₂Cl₂) LTMS CDMS MW (g/mol) Mass (g) mMol Mass (g) Mass (g) mMol Mass (g) mMol 5,000 147.2 662 39.1 2.94 30.6 10.0 105.4

Macromer Functionalization

For functionalization, the PDMS, stoichiometric amounts of allyl ether were dissolved in toluene at a concentration of 30% solids. The solutions were degassed by bubbling N₂ through them. Hydrosilylation was carried out at 60° C. in the presence of Karstedt's catalyst (1 drop of catalyst in xylene (2.1-2.4% Pt) was added). The reactions were run for 77 hours in 25-27 hour increments, but an Si—H peak remained at 4.7 ppm in ¹H NMR. Therefore, an excess of polyol was added and the reactions were run for 25 hours at 60° C. The reactions had completed (absence of Si—H peak), but residual allyl peaks were observed in ¹H NMR. Table 13 summarizes the reagent amounts used for the hydrosilylation reactions, with and without the addition of excess allyl ether. Scheme 8 shows the reaction schemes for the functionalization of the branched PDMS macromers. The allyl ethers used to synthesize branched PDMS macromers are: allyl pentaerythritol (“APE”), trimethylolpropane diallyl ether (“TMPDE”: 90% diallyl ether), trimethylolpropane monoallyl ether (“TMPME”), and allyloxyethanol (“AOE). The solvent was evaporated from the samples using the Genevac (mid-low boiling point, 12 hours, 65° C., overnight). The macromers were extracted several times with methanol to remove color and to remove the unreacted ally ether polyol.

TABLE 13 Reagent amounts for hydrosilylation of HT-PDMS-M for the functionalization of branched PDMS macromers. Allyl Excess Excess Ether Allyl Allyl allyl allyl MW PDMS PDMS ether Ether Toluene ether ether Allyl Ether (g/mol) (g) (mmol) (g) (mmol) (g) (g) (mmol) TMPME 174.3 9.66 1.93 0.34 1.93 23.33 1.50 8.61 APE 256.4 9.83 1.97 0.17 0.66 23.33 1.50 5.85 TMPDE 90 213.3 9.79 1.96 0.21 0.98 23.33 1.50 7.03 Allyloxyethanol 102.1 9.80 1.96 0.20 1.96 23.33 1.50 14.69

Macromer Characterization

The HT-PDMS-M was characterized using gel permeation chromatography (“GPC”), to confirm the molecular weight of the macromers. The branched macromers were also characterized by GPC. The number average molecular weight (“MW”), weight average MW and polydispersity index (“PDI”) of the macromers, obtained from GPC analysis, relative to polystyrene standards, are shown in Table 14.

TABLE 14 Molecular weight data for HT-PDMS-M, per GPC relative to polystyrene standards. The number and weight average MWs are shown, as well as polydispersity index. Number Weight average average Sample MW MW PDI HT-PDMS-M 5000 g/mol 5200 5900 1.1 TMPME-PDMS-M 4700 5400 1.2 APE-PDMS-M 4200 6300 1.5 TMPDE 90-PDMS-M 5400 6600 1.2 Allyloxyethanol-PDMS-M 5300 6500 1.2

Coating Formulation

Polyurethane (“PU”)—PDMS coating formulations were prepared using the APT-PDMS-Ms, isophorone diisocyanate trimer (“IDT”, 70% in butyl acetate (“BA”), Tolonate IDT 70B), a polycaprolactone polyol (“PCL”, Tone polyol 0305), dibutyltin diacetate (“DBTDAc”) as a catalyst, 2,4-pentanedione (PD) as a pot-life extender and methyl amyl ketone (“MAK”) as solvent. The PCL polyol (90% in MAK) and DBTDAc (1% in MAK) were used as solutions for formulation purposes while Tolonate IDT 70B was used as is (70% in BA). The PDMS macromers were used neat. The coatings were formulated with a 1.1:1 ratio of isocyanate to hydroxyl and amine equivalents. The coating formulations are outlined in Table 15 with reagent quantities for approximately 10 grams of total formulation. The coating formulations were prepared by first mixing the PDMS-M with the polyol solution overnight. The PD was added and the formulation was mixed. The addition of IDT 70B and DBTDAc solutions followed in that order. The coating formulations are summarized in Table 15 while their compositions are outlined in Table 16.

TABLE 15 Coating formulation recipes 90% PCL Tolonate 1% PDMS-M polyol in IDT 70B DBTDAc Coating ID (g) MAK (g) PD (g) (g) in MAK TMPE-PDMS-M-10 0.750 2.39 0.98 6.57 0.11 TMPE-PDMS-M-5 0.375 2.54 0.99 6.91 0.11 TMPE-PDMS-M-1 0.075 2.66 1.00 7.18 0.11 APE-PDMS-M 10 0.750 2.39 0.98 6.57 0.11 APE-PDMS-M-5 0.375 2.54 0.99 6.91 0.11 APE-PDMS-M-1 0.075 2.66 1.00 7.18 0.11 TMPDE 90-PDMS-M-10 0.750 2.39 0.98 6.57 0.11 TMPDE 90-PDMS-M-5 0.375 2.54 0.99 6.91 0.11 TMPDE 90-PDMS-M-1 0.075 2.66 1.00 7.18 0.11 Allyloxyethanol-PDMS-M- 0.750 2.39 0.98 6.57 0.11 10 Allyloxyethanol-PDMS-M-5 0.375 2.54 0.99 6.91 0.11 Allyloxyethanol-PDMS-M-1 0.075 2.66 1.00 7.18 0.11

TABLE 16 Coating formulation compositions PD Weight % of Solids DBTDAc Weight % of (based PCL Total (based on Solvent on total Coating ID PDMS-M IDT polyol Solids total solids) BA MAK formulation) TMPE-PDMS-M-10 10% 61% 29% 76% 0.015% 85% 15% 10% TMPE-PDMS-M-5 5% 65% 30% 75% 0.015% 85% 15% 10% TMPE-PDMS-M-1 1% 67% 32% 75% 0.015% 85% 15% 10% APE-PDMS-M 10 10% 61% 29% 76% 0.015% 85% 15% 10% APE-PDMS-M-5 5% 65% 30% 75% 0.015% 85% 15% 10% APE-PDMS-M-1 1% 67% 32% 75% 0.015% 85% 15% 10% TMPDE 90-PDMS-M- 10% 61% 29% 76% 0.015% 85% 15% 10% 10 TMPDE 90-PDMS-M-5 5% 65% 30% 75% 0.015% 85% 15% 10% TMPDE 90-PDMS-M-1 1% 67% 32% 75% 0.015% 85% 15% 10% Allyloxyethanol-PDMS- 10% 61% 29% 76% 0.015% 85% 15% 10% M-10 Allyloxyethanol-PDMS- 5% 65% 30% 75% 0.015% 85% 15% 10% M-5 Allyloxyethanol-PDMS- 1% 67% 32% 75% 0.015% 85% 15% 10% M-1

Pseudobarnacle Adhesion

Pseudobarnacle adhesion (“PB”) was performed on the coatings approximately 20 hours after initial attachment of the studs. This was performed on the as-made samples. The results from this test are shown in Table 17. The three reported values are averages of three measurements, unless otherwise noted. The samples prepared with Allyloxyethanol-PDMS-M were delaminated at the substrate-coating surface (or the adhesive was left on the coating and delamination occurred between the PB and the epoxy) when the PB was removed. A similar observation was made for one or more testing replicates of the following samples: TMPE-PDMS-M-5, and TMPE-PDMS-M-1.

TABLE 17 Pseudobarnacle adhesion results before water immersion. Before Water Immersion Average Release Force Coating (N) Std Dev (N) TMPE-PDMS-M-10 8.0 0.2 TMPE-PDMS-M-5 31.3 25.6 TMPE-PDMS-M-1 60.8 16.6 APE-PDMS-M-10 29.7 22.2 APE-PDMS-M-5 8.0 0.0 APE-PDMS-M-1 8.2 0.2 TMPDE 90-PDMS-M-10 8.0 0.2 TMPDE 90-PDMS-M-5* 7.9 0.1 TMPDE 90-PDMS-M-1 8.2 0.8 Allyloxyethanol-PDMS-M-10 37.3 3.9 Allyloxyethanol-PDMS-M-5 37.9 16.0 Allyloxyethanol-PDMS-M-1 49.9 28.0 *Only 2 measurements were included (3rd was near 1N and determined as an outlier)

Contact Angle and Surface Energy

Contact angle (“CA”) measurements were performed on coatings on 3′×6″ aluminum panels using water and methylene iodide (“MeI”). Table 18 summarizes the water and MeI contact angles, along with surface energy (“SE”). The reported values are the averages of three measurements.

TABLE 18 Water and methylene iodide (“Mel”) contact angle measurements on experimental coatings. The values are the averages of three measurements Water MeI CA Std CA Std SE Coating (°) Dev (°) (°) Dev (°) (nN/m) TMPE-PDMS-M-10 88.1 1.5 45.9 1.4 38.3 TMPE-PDMS-M-5 90.4 0.2 43.1 5.2 39.1 TMPE-PDMS-M-1 95.0 1.4 56.1 1.9 31.9 APE-PDMS-M 10 88.4 0.8 46.2 2.8 38.0 APE-PDMS-M-5 89.3 1.2 47.6 3.4 37.2 APE-PDMS-M-1 97.3 1.2 49.1 7.3 35.1 TMPDE 90-PDMS-M-10 92.4 3.1 47.3 4.5 36.7 TMPDE 90-PDMS-M-5 91.0 0.3 49.1 3.2 36.1 TMPDE 90-PDMS-M-1 97.2 0.5 46.5 6.3 36.5 Allyloxyethanol-PDMS-M- 86.5 1.5 32.6 2.1 44.4 10 Allyloxyethanol-PDMS-M-5 87.5 0.9 26.3 1.8 46.5 Allyloxyethanol-PDMS-M-1 84.7 3.6 33.6 3.6 44.4

Illustrative Embodiments

Reference is made in the following to a number of illustrative embodiments of the subject matter described herein. The following embodiments describe illustrative embodiments that may include the various features, characteristics, and advantages of the subject matter as presently described. Accordingly, the following embodiments should not be considered as being comprehensive of all of the possible embodiments.

One embodiment provides polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyol; and a polysiloxane component having two or more polyorganosiloxane chains attached to a linker molecule, which has one or more functional groups capable of reacting with the polyisocyanate. Optionally the polysiloxane component has a formula I:

where R′Si— is a terminal group; n is about 10 to 1,000; LINK is a linking group; X is —OH or —NH2; and y is an integer from 1 to 4. Optionally the LINK is an alkylene group which may have one or more oxygen, nitrogen or sulfur atoms substituted for a carbon atom of its backbone. Optionally the LINK has no more than about 10 atoms in its backbone. Suitable R′Si— terminal groups may be trialkylsilyl groups, such as R₃Si— groups, e.g., Me₃Si—, or R¹R₂Si— groups, e.g., BuMe₂Si—. Optionally the mixture has a ratio of (isocyanate groups)/(amine+alcohol groups) of about 1.0 to 1.2. Optionally, the polyisocyanate comprises hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof. Optionally the polyol comprises hydroxy-functional poly(meth)acrylate. Optionally the polyol comprises polycaprolactone polyol. Optionally the hydroxy-functional poly(meth)acrylate is formed from a monomer mixture comprising hydroxyalkyl acrylate and alkyl acrylate. Optionally the mixture is a coating composition. Optionally the mixture comprises about 30 to 85 wt. % of the polyisocyanate.

Another embodiment provides polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane having two or more functional groups capable of reacting with the polyisocyanate attached to only a single end of the polyorganosiloxane; and polyol. Optionally the polyorganosiloxane has (a) two or more amino groups or, (b) two or more hydroxy groups attached to only a single end of the polyorganosiloxane. Optionally the mixture has a ratio of (isocyanate groups)/(amine+alcohol groups) of about 1.0 to 1.2. Optionally, the polyisocyanate comprises hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof. Optionally the polyol comprises hydroxy-functional poly(meth)acrylate. Optionally the polyol comprises polycaprolactone polyol. Optionally the hydroxy-functional poly(meth)acrylate is formed from a monomer mixture comprising hydroxyalkyl acrylate and alkyl acrylate. Optionally the polyorganosiloxane has a number average molecular weight of about 500 to 30,000. Optionally the mixture is a coating composition. Optionally the mixture comprises about 30 to 85 wt. % of the polyisocyanate.

Another embodiment provides polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane having one or more hydroxyl alkyl carbamate groups attached to only a single end of the polyorganosiloxane; and polyol. Optionally the mixture has a ratio of (isocyanate groups)/(amine+alcohol groups) of about 1.0 to 1.2. Optionally, the polyisocyanate comprises hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof. Optionally the polyol comprises hydroxy-functional poly(meth)acrylate. Optionally the polyol comprises polycaprolactone polyol. Optionally the hydroxy-functional poly(meth)acrylate is formed from a monomer mixture comprising hydroxyalkyl acrylate and alkyl acrylate. Optionally the polyorganosiloxane has a number average molecular weight of about 500 to 30,000. Optionally the mixture is a coating composition. Optionally the mixture comprises about 30 to 85 wt. % of the polyisocyanate.

Another embodiment provides a polymeric material prepared by reacting a mixture comprising: a polyorganosiloxane having one or more amino groups, wherein the amino groups are attached to only a single end of the polyorganosiloxane; polyisocyanate; and polyol. Optionally the polyorganosiloxane includes poly(dialkylsiloxane) having one or more amino groups attached thereto.

Another embodiment provides a method of inhibiting fouling on a surface exposed to aqueous conditions comprising applying the coating composition of any of paragraphs [0068] to [0071] above.

Another embodiment provides a substrate having a surface capable of being exposed to aqueous conditions; wherein the surface has a fouling release coating thereon; and the coating comprises the polymeric material of any of paragraphs [0068] to [0071] above. Optionally the coating may have an initial water contact angle of at least about 100°. Optionally the water contact angle changes by no more than about 10° after immersion in deionized water for 30 days. Optionally the coating may have an initial pseudobarnacle pull off adhesion release force of no more than about 80 N.

Another embodiment provides a method of inhibiting fouling on a surface exposed to aqueous conditions comprising applying a fouling release coating composition to the surface where the coating composition comprises: about 2 to 20 wt. % (on a solids basis) of an amino functional polyorganosiloxane; from about 30 wt. % to 85 wt. % (on a solids basis) of polyisocyanate; and polyol. Optionally the polyorganosiloxane has a number average molecular weight of about 1,000 to 20,000 and has one or more amino groups attached to only a single end of the polymer; and the coating composition has a ratio of (isocyanate groups)/(amine+alcohol groups) of about 1.05 to 1.15.

One embodiment provides a polymeric material prepared by reacting a mixture comprising: an amino functional polyorganosiloxane that has one or more amino groups attached to only a single end of the polymer chain; polyisocyanate; and polyol. Optionally, the polymeric material may have an initial water contact angle of at least about 90°. Optionally the water contact angle may change no more than about 10° after immersion in deionized water for 30 days. Optionally the polymeric material may have an initial pseudobarnacle pull off adhesion release force of no more than about 80 N. Optionally the amino functional polyorganosiloxane may include poly(dialkylsiloxane) having one or more amino groups attached to only a single end of the polymer chain.

Another embodiment provides a method of inhibiting fouling on a surface exposed to aquatic conditions including applying a fouling release coating composition to the surface, where the coating composition comprises: an amino functional polyorganosiloxane; polyisocyanate; and polyol. Optionally the amino functional polyorganosiloxane may have one or more amino groups attached to only a single end of the polymer chain. Optionally the polyisocyanate may comprise hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof. Optionally, the amino functional polyorganosiloxane may have a number average molecular weight of about 500 to 30,000. Optionally the amino functional polyorganosiloxane may have a number average molecular weight of at least about 2,000. Optionally the amino functional polyorganosiloxane may have a number average molecular weight of at least about 10,000.

Another embodiment provides a substrate having a surface capable of being exposed to aquatic conditions, where the surface has a fouling release coating thereon, and the coating comprises a polymeric material prepared by reacting a mixture comprising: an amino functional polysiloxane, where the polysiloxane has one or more amino groups attached to only a single end of the polymer chain; polyisocyanate; and polyol. Optionally the amino functional polysiloxane coating composition comprises an amino functional polyorganosiloxane. Optionally the mixture comprises about 30 wt % to 85 wt % of polyisocyanate. Optionally the polyol may comprise hydroxy-functional poly(meth)acrylate. Optionally the hydroxy-functional poly(meth)acrylate may be formed from a monomer mixture comprising hydroxyalkyl acrylate and alkyl acrylate. Optionally the hydroxy-functional poly(meth)acrylate may include hydroxyethyl acrylate/butyl acrylate copolymer. Optionally the polyol may comprise polycaprolactone polyol.

One embodiment provides a polymeric material prepared by reacting a mixture comprising polyorganosiloxane having functional groups capable of reacting with the polyisocyanate, wherein the polyorganosiloxane comprises polyorganosiloxane having one or more amino groups attached to only a single end of the polymer; polyisocyanate; and polyol. Optionally, the polyorganosiloxane may comprise amino-functional poly(dialkylsiloxane) having one or more amino groups attached to only a single end of the polymer chain. Optionally, the polyorganosiloxane may comprise amino-functional poly(dimethylsiloxane) having amino groups attached to only a single end of the polymer chain. Optionally, the amino-functional poly(dimethylsiloxane) is an aminoalkyl terminated poly(dimethylsiloxane), such as aminopropyl terminated poly(dimethylsiloxane) or aminoethyl terminated poly(dimethylsiloxane).

Another embodiment provides a method of inhibiting fouling on a surface exposed to aquatic conditions comprising applying a fouling release coating composition to the surface where the coating composition comprises: from about 2 wt. % to 20 wt. % (on a solids basis) of an amino functional polyorganosiloxane; from about 30 wt. % to 85 wt. % (on a solids basis) of polyisocyanate; and polyol. Optionally the coating composition may have a ratio of (isocyanate groups)/(amine and alcohol groups) of about 1.0 to 1.2. Optionally the coating composition may have a ratio of (isocyanate groups)/(amine and alcohol groups) of about 1.05 to 1.15. Optionally the coating composition may comprise about 5 wt % to 15 wt % (on a solids basis) of the amino functional polyorganosiloxane. Optionally the amino functional polyorganosiloxane may have a number average molecular weight of about 500 to 30,000. Optionally the amino functional polyorganosiloxane may have a number average molecular weight of about 1,000 to 20,000. Optionally the polyisocyanate may comprise hexamethylene diisocyanate trimer, isophorone diisocyanate trimer or a mixture thereof.

Another embodiment provides a method of inhibiting fouling on a surface exposed to aquatic conditions comprising applying a fouling release coating composition to the surface, where the coating composition comprises: from about 2 wt % to 20 wt % (on a solids basis) of an amino functional polyorganosiloxane, where the polyorganosiloxane may have a number average molecular weight of about 1,000 to 20,000 and may comprise polyorganosiloxane having one or more amino groups attached to only a single end of the polymer; polyisocyanate; and polyol, where the coating composition has a ratio of (isocyanate groups)/(amine and alcohol groups) of about 1.05 to 1.15.

Another embodiment provides a polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane that may have one or more functional groups capable of reacting with the polyisocyanate attached to only a single end of the polyorganosiloxane; and polyol. Optionally the polyorganosiloxane may have (a) two or more amino groups or, (b) two or more hydroxy groups attached to only a single end of the polyorganosiloxane.

Another embodiment provides a polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane that may have one or more functional groups capable of reacting with the polyisocyanate attached to only a single end of the polyorganosiloxane and where the polyorganosiloxane may comprise polyorganosiloxane that may have a hydroxyl alkyl carbamate group attached to only a single end of the polyorganosiloxane; and polyol.

Another embodiment provides a polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane that may have one or more functional groups capable of reacting with the polyisocyanate; and polyol.

Another embodiment provides a polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane having one or more hydroxyl alkyl carbamate groups attached to only a single end of the polyorganosiloxane; and polyol.

Another embodiment provides a polymeric material prepared by reacting a mixture comprising: polyisocyanate; two or more polyorganosiloxanes attached to a linker molecule having one or more functional groups capable of reacting with the polyisocyanate; and polyol.

One embodiment (A) provides a method of inhibiting fouling on a boat hull comprising applying a fouling release coating composition to at least a portion of the hull, where the coating composition comprises a polymeric material prepared by reacting a mixture comprising: an amino functional polyorganosiloxane having one or more amino groups attached to a single end of the polyorganosiloxane; polyisocyanate; and polyol.

The amino functional polyorganosiloxane used in embodiment (A) may optionally have a number average molecular weight of at least about 500; commonly no more than about 50,000; e.g., an amino functional polyorganosiloxane having a number average molecular weight of about 1,000 to 30,000; and, desirably, about 1,000 to 5,000. The amino functional polyorganosiloxane may typically be an amino functional poly(dialkylsiloxane) having one or two amino groups connected to a single end of the poly amino functional polyorganosiloxane, e.g., covalently linked to the amino functional polyorganosiloxane through an alkylene or cycloalkylene linking group. For example, the amino functional polyorganosiloxane may be an aminoalkyl terminated poly(dialkylsiloxane), such as an aminoethyl or aminopropyl terminated PDMS. The amino functional poly(dialkylsiloxane) may have a number average molecular weight of at least about 500 and, more commonly, about 1,000 to 5,000.

The polymeric material of embodiment (A) may have an initial water contact angle of at least about 70°. The polymeric material may optionally have a water contact angle that changes no more than about 20° after immersion in deionized water for 30 days. More desireably, the polymeric material may have an initial water contact angle of at least about 80° and, in some instances, may have an initial water contact angle of about 90° or higher.

The polymeric material of embodiment (A) may have an initial pseudobarnacle pull off adhesion release force of no more than about 80 N. In some instances, the polymeric material may have an initial pseudobarnacle pull off adhesion release force of no more than about 50 N and, in some instances, may have an initial pseudobarnacle pull off adhesion release force of no more than about 15 N.

Another embodiment (B) provides a substrate, such as a boat hull, having fouling release coating on a surface thereof; where the coating comprises a polymeric material prepared by reacting a mixture comprising: an amino functional poly(dialkylsiloxane) having one or more amino groups attached to a single end of the polyorganosiloxane; polyisocyanate; and polyol. Optionally, the substrate may comprise a coating that may have an initial pseudobarnacle pull off adhesion release force of no more than about 60 N. Optionally the coating may have an initial water contact angle of at least about 70°. Optionally the coating may have a water contact angle which may change no more than about 20° after immersion in deionized water for 30 days. Optionally the coating may have a water contact angle that may change no more than about 15° after immersion in deionized water for 30 days. Optionally the coating may have a water contact angle that may change no more than about 10° after immersion in deionized water for 30 days.

One embodiment (C) provides a polymeric material prepared by reacting a mixture comprising: an amino functional poly(dialkylsiloxane) having one or more amino groups attached to a single end of the polyorganosiloxane; polyisocyanate; and polyol. Optionally, the polymeric material may have an initial water contact angle of at least about 70°. Optionally, the polymeric material may have an initial water contact angle of at least about 80°. Optionally, the polymeric material may have an initial water contact angle of at least about 90°.

Optionally, the polymeric material of embodiment (C) may have a water contact angle that changes no more than about 20° after immersion in deionized water for 30 days. Optionally, the polymeric material may have a water contact angle that changes no more than about 15° after immersion in deionized water for 30 days. Optionally, the polymeric material may have a water contact angle that changes no more than about 10° after immersion in deionized water for 30 days.

The polymeric material of embodiment (C) may optionally have an initial pseudobarnacle pull off adhesion release force of no more than about 60 N. Optionally the polymeric material may have an initial pseudobarnacle pull off adhesion release force of no more than about 50 N. Optionally the polymeric material may have an initial pseudobarnacle pull off adhesion release force of no more than about 30 N. Optionally the polymeric material may have an initial pseudobarnacle pull off adhesion release force of no more than about 15 N.

The amino functional polyorganosiloxane of embodiment (C) may have a number average molecular weight of at least about 500; commonly no more than about 50,000; e.g., amino functional polyorganosiloxane having a number average molecular weight of about 1,000 to 30,000; and, desirably, about 1,000 to 5,000.

The amino functional polyorganosiloxane of embodiment (C) may typically be an amino functional poly(dialkylsiloxane) having one or two amino groups connected to a single end of the poly amino functional polyorganosiloxane, e.g., covalently linked to the amino functional polyorganosiloxane through an alkylene or cycloalkylene linking group. Optionally, the amino functional polyorganosiloxane may have a number average molecular weight of at least about 2000; and often about 2,000 to 5,000 may be quite suitable for use in forming the present coatings.

In embodiment (C), the ratio of isocyanate groups to hydroxyl plus amino groups in the mixture may be at least 1.0. Optionally, the ratio of isocyanate groups to hydroxyl plus amino groups in the mixture may be 1.05 to 1.2. Optionally, the amino functional polyorganosiloxane may have a number average molecular weight of no more than about 50,000, preferably about 5,000 to 30,000, and more preferably about 10,000 to 25,000. Optionally, the ratio of isocyanate groups to hydroxyl plus amino groups in the mixture may be at least 1.0. Optionally, the polyol may include polyol having at least three hydroxy groups and/or the polyisocyanate includes diisocyanate trimer.

The polymeric material of embodiment (C) may comprise about 5 wt % to 30 wt % of the amino functional polyorganosiloxane. Optionally the polyol of embodiment (C) may comprise polycaprolactone polyol. Optionally the polyol may comprise hydroxy-functional poly(meth)acrylate. Optionally, the hydroxy-functional poly(meth)acrylate of embodiment (C) may be formed from a monomer mixture comprising hydroxyalkyl acrylate and alkyl acrylate. Optionally, the hydroxy-functional poly(meth)acrylate may be formed from a monomer mixture comprising hydroxyalkyl acrylate, alkyl acrylate and alkyl methacrylate. Optionally the mixture of embodiment (C) may comprise about 30 wt % to 85 wt % of polyisocyanate. Optionally the polyol of embodiment (C) may comprise a polycaprolactone polyol, e.g., where the polycaprolactone polyol may comprise polycaprolactone triol having an average hydroxyl equivalent weight of about 150 to 200. Optionally the polyisocyanate of embodiment (C) may have an average isocyanate equivalent weight of about 150 to 600, and desirably about 250 to 450. Optionally, the polyisocyanate may comprise isophorone diisocyanate, hexamethylene diisocyanate, oligomers thereof or a mixture thereof.

In another embodiment (D) a crosslinked polysiloxane-modified polyurethane coating may be formed from a mixture comprising: an amino functional polyorganosiloxane that may have one or more amino groups attached to a single end of the polyorganosiloxane; polyisocyanate; and polyol. Optionally, the polyorganosiloxane may be a mono-amino functional polydialkylsiloxane. Optionally, the polyorganosiloxane may be a mono-amino functional polydimethylsiloxane. Optionally, the polyorganosiloxane may be an aminoalkyl terminated polydimethylsiloxane having amino group(s) only on a single end of the polysiloxane chain.

One embodiment (E) provides polymeric material that may be prepared by reacting a composition comprising: polyol; polyisocyanate; and amino functional poly(dialkylsiloxane) having one or more functional groups, such as an amino group, capable of reacting with the polyisocyanate. Optionally, the amino functional poly(dialkylsiloxane) may have a number average molecular weight of at least about 1,000. The amino functional poly(dialkylsiloxane) may typically be an amino functional poly(dimethylsiloxane) having an alkylamino group on a single end (i.e., an amino group connected to the end of the polysiloxane chain. Often, the amino functional poly(dimethylsiloxane) may include about 10 to 50 subunits.

Another embodiment (F) provides a substrate that may have a surface capable of being exposed to aquatic conditions, where the surface has a fouling release coating thereon, and where the coating comprises a polymeric material prepared by reacting a mixture comprising: an amino functional poly(dialkylsiloxane) having one or more amino groups attached to a single end of the polyorganosiloxane; polyisocyanate; and polyol. Optionally, the polyorganosiloxane may be a mono-amino functional polydialkylsiloxane. Optionally, the polyorganosiloxane may be a mono-amino functional polydimethylsiloxane. Optionally, the polyorganosiloxane may be an aminoalkyl terminated polydimethylsiloxane having amino group(s) only on a single end of the polysiloxane chain. Optionally, the polyol may comprise hydroxy-functional poly(meth)acrylate. Optionally, the polyol may comprise polycaprolactone triol. Optionally, the polyol may comprise hydroxy-functional poly(meth)acrylate. Optionally, the polyisocyanate may comprise hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof. Optionally, the surface exposed to aquatic conditions may be a surface exposed to salt water. Optionally, the surface exposed to aquatic conditions may be a surface exposed to fresh water.

It will be readily apparent to one skilled in the art that varying substitutions and modifications may be made to the methods and compositions disclosed herein without departing from the scope and spirit of the invention. The invention illustratively described herein suitably may be practiced in the absence of any element or elements, limitation or limitations which is not specifically disclosed herein. The terms and expressions which have been employed are used as terms of description and not of limitation, and there is no intention that in the use of such terms and expressions of excluding any equivalents of the features shown and described or portions thereof, but it is recognized that various modifications are possible within the scope of the invention. Thus, it should be understood that although the present invention has been illustrated by specific embodiments and optional features, modification and/or variation of the concepts herein disclosed may be resorted to by those skilled in the art, and that such modifications and variations are considered to be within the scope of this invention.

In addition, where features or aspects of the invention are described in terms of Markush groups or other grouping of alternatives, those skilled in the art will recognize that the invention is also thereby described in terms of any individual member or subgroup of members of the Markush group or other group.

Also, unless indicated to the contrary, where various numerical values are provided for embodiments, additional embodiments are described by taking any 2 different values as the endpoints of a range. Such ranges are also within the scope of the described invention. 

1. A polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyol; and a polysiloxane component having two or more polyorganosiloxane chains attached to a linker group, which has one or more functional groups capable of reacting with the polyisocyanate attached thereto.
 2. The polymeric material of claim 1, wherein the polysiloxane component has a formula I:

where R′Si— is a terminal group; n is about 10 to 1,000; LINK is a linking group; X is —OH or —NH₂; and y is an integer from 1 to
 4. 3. The polymeric material of claim 2, wherein the LINK is an alkylene group, which may have one or more oxygen, nitrogen or sulfur atoms substituted for a carbon atom of its backbone; the LINK has no more than about 10 atoms in its backbone; and R′Si— is a trialkylsilyl group. 4-5. (canceled)
 6. A polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane having two or more functional groups capable of reacting with the polyisocyanate attached to only a single end of the polyorganosiloxane; and polyol.
 7. The polymeric material of claim 6, wherein the polyorganosiloxane has (a) two or more amino groups or (b) two or more hydroxy groups attached to only a single end of the polyorganosiloxane. 8-25. (canceled)
 26. The polymeric material of claim 1, wherein the linker molecule has one or more amino groups attached thereto; the polyisocyanate comprises hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof; and the polyol comprises hydroxy-functional poly(meth)acrylate, polycaprolactone polyol, or a mixture thereof.
 27. A polymeric material prepared by reacting a mixture comprising: polyisocyanate; polyorganosiloxane having one or more reactive functional groups attached to only a single end of the polyorganosiloxane; and polyol; wherein the reactive functional groups are hydroxyl alkyl carbamate groups or amino groups.
 28. The polymeric material of claim 27, wherein the polyorganosiloxane includes poly(dialkylsiloxane) having one or more amino groups attached to only a single end.
 29. The polymeric material of claim 27, wherein the mixture has a ratio of (isocyanate groups)/(amine+alcohol groups) of about 1.0 to 1.2.
 30. The polymeric material of claim 27, wherein the polyisocyanate comprises hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof.
 31. The polymeric material of claim 27, wherein the polyol comprises hydroxy-functional poly(meth)acrylate, polycaprolactone polyol, or a mixture thereof.
 32. A coating composition comprising the mixture according to claim
 27. 33. A method of inhibiting fouling on a surface exposed to aqueous conditions comprising applying the coating composition of claim 32 to the surface.
 34. A substrate having a surface capable of being exposed to aqueous conditions; wherein the surface has a coating thereon; and the coating comprises the polymeric material of claim
 27. 35. The substrate of claim 34, wherein the coating has an initial water contact angle of at least about 100°.
 36. The substrate of claim 35, wherein the water contact angle of the coating changes by no more than about 10° after immersion in deionized water for 30 days.
 37. The substrate of claim 34, wherein the coating has an initial pseudobarnacle pull off adhesion release force of no more than about 80 N.
 38. A method of inhibiting fouling on a surface exposed to aqueous conditions comprising applying the coating composition of claim 32 to the surface; wherein the coating composition comprises: about 2 to 20 wt. % (on a solids basis) of an amino functional polyorganosiloxane, wherein the amino functional polyorganosiloxane has one or more amino groups attached to only a single end of the polyorganosiloxane; from about 30 wt. % to 85 wt. % (on a solids basis) of polyisocyanate; and polyol.
 39. The method of claim 38, wherein the polyorganosiloxane has a number average molecular weight of about 1,000 to 20,000; the polyisocyanate comprises hexamethylene diisocyanate trimer, isophorone diisocyanate trimer, or a mixture thereof; and the coating composition has a ratio of (isocyanate groups)/(amine+alcohol groups) of about 1.05 to 1.15.
 40. A substrate having a surface capable of being exposed to aqueous conditions; wherein the surface has a fouling release coating thereon; the fouling release coating comprises the polymeric material of claim 6; the fouling release coating has an initial pseudobarnacle pull off adhesion release force of no more than about 80 N; the fouling release coating has an initial water contact angle of at least about 100°; and the water contact angle of the fouling release coating changes by no more than about 10° after immersion in deionized water for 30 days. 